hydrokinetics

简明释义

英[ˌhaɪdrəʊkaɪˈnetɪks]美[ˈhaɪdrəkaɪˈnetɪks]

n. [流] 流体动力学；液体动力学

英英释义

单词用法

同义词

反义词

例句

1.Based on the hydrokinetics and the multiphase flow theory, the paper studied the motion Of sand and water's in the axial flow turbine, silt wear and the feature Of flow.

从流体动力学出发，研究了水轮机过流部件中的沙水运动、包括泥沙磨损机理、流动特性等。

2.Think of it as the Bonneville Salt Flats of hydrokinetics: EMEC offers companies a place to try out their clean tech.

可以把它看成是巴纳维亚盐带平地的流体动力学：应急医疗教育为企业提供一个地方试试自己的清洁技术。

3.An automatic topdressing system was designed on the base of the principle of hydrokinetics using energy of static pressure for pipe irrigation and the feature of Venturi pipe in solar greenhouse.

依据流体动力学原理，利用日光温室管网灌溉的静压能和文丘里管的特性，设计出在日光温室正常灌溉情况下的自动施肥系统。

4.Using the knowledge of the hydrokinetics theory and combining experimentation, created the modal of the medium-balls' movement in Annular Gap Affritor.

运用流体动力学理论知识，结合试验，建立了环缝磨内介质球的运动模型；

5.The algorithm for body-fitted coordinate grids generation is one of the key techniques of numerical simulation in hydrokinetics.

贴体坐标网格生成算法是流体动力学等领域中进行数值模拟的关键技术问题。

6.The computer simulation of fluid flow in pit furnace when large sized gears gas carburized has been done using the theory of hydrokinetics.

利用流体动力学的基本原理用计算机模拟了大尺寸齿轮在井式渗碳炉内进行气体渗碳时的流场分布。

7.An automatic topdressing system was designed on the base of the principle of hydrokinetics using energy of static pressure for pipe irrigation and the feature of Venturi pipe in solar greenhouse.

依据流体动力学原理，利用日光温室管网灌溉的静压能和文丘里管的特性，设计出在日光温室正常灌溉情况下的自动施肥系统。

8.The model about performance analysis of seal which is 3D is put forward on the basis of lucubration, and hydrokinetics model of static axial symmetry is established.

简要介绍了刷密封的历史和应用前景，并在深入研究的基础上，总结和提出了刷式密封准三维的性能分析模型，建立了静态轴对称的流体动力学模型。

9.For this, foreign some company is a foundation with the hydrokinetics, pass current analysis, studied the efflux feature of weak opening and poriferous oxygen gun.

为此，国外某公司以流体动力学为基础，通过液流分析，探究了单孔和多孔氧枪的射流特征。

10.By introducing the method of rotation operator, we study the singular limits for the boundary problem of rigid wall in hydrokinetics equations.

采用旋度算子的方法研究流体动力学方程组固壁边界问题的奇异极限。

11.In environmental science, hydrokinetics helps predict how pollutants disperse in rivers.

在环境科学中，水动力学有助于预测污染物在河流中的扩散。

12.The principles of hydrokinetics are applied in the development of wave energy converters.

在波浪能转换器的开发中应用了水动力学的原理。

13.Researchers in hydrokinetics explore the effects of water flow on aquatic ecosystems.

从事水动力学研究的科学家探讨水流对水生生态系统的影响。

14.The study of hydrokinetics involves understanding the motion of fluids, particularly water.

对水动力学的研究涉及理解流体，特别是水的运动。

15.Engineers use hydrokinetics to design more efficient water turbines.

工程师利用水动力学设计更高效的水轮机。

作文

In the realm of physics and engineering, the study of fluid dynamics is crucial for understanding how fluids behave under various conditions. One fascinating subfield of this study is known as hydrokinetics, which focuses on the motion of fluids and the forces acting upon them. This discipline is not only vital for theoretical research but also has practical applications in various industries, including aerospace, civil engineering, and environmental science. Hydrokinetics can be defined as the branch of science that deals with the movement of fluids, particularly water, and the effects of that movement on surrounding structures and environments. The principles of hydrokinetics are employed in designing efficient transportation systems, such as ships and submarines, where understanding the interaction between water and the vehicle is essential for optimizing speed and fuel efficiency. For instance, engineers must consider the shape and size of a vessel to minimize drag and enhance stability while navigating through water. The knowledge gained from hydrokinetics allows for the creation of streamlined designs that can cut through water more efficiently, reducing resistance and improving performance.Additionally, hydrokinetics plays a significant role in environmental management, particularly in the study of rivers, lakes, and oceans. Understanding the flow of water helps scientists predict erosion patterns, sediment transport, and the dispersion of pollutants. By applying the principles of hydrokinetics, researchers can develop better strategies for preserving aquatic ecosystems and mitigating the impact of human activities on natural water bodies.Moreover, the field of hydrokinetics is not limited to just natural bodies of water; it also extends to artificial systems such as pipelines and irrigation channels. Engineers utilize hydrokinetics to design these systems effectively, ensuring that water flows smoothly and efficiently to where it is needed most. This is particularly important in agriculture, where proper irrigation techniques can significantly affect crop yields and sustainability.Another exciting application of hydrokinetics is in renewable energy generation. Hydropower plants harness the kinetic energy of flowing water to produce electricity. Understanding the principles of hydrokinetics is essential for optimizing turbine designs and maximizing energy output. As the world seeks cleaner and more sustainable energy sources, the importance of hydrokinetics in developing efficient hydropower systems cannot be overstated.In conclusion, hydrokinetics is a vital area of study that intersects with numerous fields and has far-reaching implications for both technology and the environment. Whether in designing faster and more efficient vehicles, managing water resources, or generating renewable energy, the principles of hydrokinetics provide invaluable insights that help us navigate the complexities of fluid motion. As we continue to explore and understand the intricacies of this fascinating field, it becomes increasingly clear that hydrokinetics will play a pivotal role in shaping our future, particularly in an era where environmental sustainability is paramount.

在物理和工程领域，流体动力学的研究对于理解流体在各种条件下的行为至关重要。这个研究的一个迷人子领域被称为水动力学，它专注于流体的运动及其所受的力。这一学科不仅对理论研究至关重要，还有在航空航天、土木工程和环境科学等多个行业的实际应用。水动力学可以定义为研究流体，特别是水的运动及其对周围结构和环境影响的科学分支。水动力学的原理被用于设计高效的交通系统，例如船舶和潜艇，在这些系统中，了解水与车辆之间的相互作用对于优化速度和燃料效率至关重要。例如，工程师必须考虑船只的形状和大小，以最小化阻力并增强在水中航行时的稳定性。从水动力学中获得的知识使得设计出流线型的设计成为可能，这样的设计能够更有效地切割水流，减少阻力，提高性能。此外，水动力学在环境管理中也发挥着重要作用，尤其是在对河流、湖泊和海洋的研究中。理解水流的行为有助于科学家预测侵蚀模式、沉积物运输和污染物的扩散。通过应用水动力学的原理，研究人员可以制定更好的策略来保护水生生态系统，并减轻人类活动对自然水体的影响。此外，水动力学的领域不仅限于自然水体；它还扩展到人工系统，例如管道和灌溉渠道。工程师利用水动力学来有效地设计这些系统，确保水流畅通无阻，并高效地流向最需要的地方。这在农业中尤为重要，适当的灌溉技术可以显著影响作物产量和可持续性。水动力学的另一个令人兴奋的应用是在可再生能源发电中。水电站利用流动水的动能来生产电力。理解水动力学的原理对于优化涡轮机设计和最大化能量输出至关重要。随着世界寻求更清洁、更可持续的能源来源，水动力学在开发高效水电系统中的重要性不容小觑。总之，水动力学是一个重要的研究领域，涉及多个领域，并对技术和环境具有深远的影响。无论是在设计更快、更高效的交通工具、管理水资源还是发电，可再生能源的原则都提供了宝贵的见解，帮助我们应对流体运动的复杂性。随着我们继续探索和理解这一迷人领域的细微差别，越来越明显的是，水动力学将在塑造我们的未来方面发挥关键作用，特别是在环境可持续性至关重要的时代。